#include <AliRunLoader.h> //Stack()
#include <AliStack.h> //Stack()
#include <TParticle.h> //Stack()
-#include "AliHMPIDHelix.h" //TestTrans()
+#include <TGeoPhysicalNode.h> //ctor
ClassImp(AliHMPIDParam)
AliHMPIDParam* AliHMPIDParam::fgInstance=0x0; //singleton pointer
//++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
-AliHMPIDParam::AliHMPIDParam():TNamed("RichParam","default version")
+AliHMPIDParam::AliHMPIDParam():TNamed("HmpidParam","default version")
{
// Here all the intitializition is taken place when AliHMPIDParam::Instance() is invoked for the first time.
// In particulare, matrices to be used for LORS<->MARS trasnformations are initialized from TGeo structure.
// Note that TGeoManager should be already initialized from geometry.root file
fX=0.5*AliHMPIDDigit::SizeAllX();
fY=0.5*AliHMPIDDigit::SizeAllY();
- for(Int_t i=0;i<7;i++)
- if(gGeoManager)
- fM[i]=(TGeoHMatrix*)gGeoManager->GetVolume("ALIC")->GetNode(Form("HMPID_%i",i))->GetMatrix();
- else{
+ for(Int_t i=AliHMPIDDigit::kMinCh;i<=AliHMPIDDigit::kMaxCh;i++)
+ if(gGeoManager && gGeoManager->IsClosed()) {
+// fM[i]=(TGeoHMatrix*)gGeoManager->GetVolume("ALIC")->GetNode(Form("HMPID_%i",i))->GetMatrix(); // previous style
+ TGeoPNEntry* pne = gGeoManager->GetAlignableEntry(Form("/HMPID/Chamber%i",i));
+ if (!pne) {
+ AliErrorClass(Form("The symbolic volume %s does not correspond to any physical entry!",Form("HMPID_%i",i)));
+ fM[i]=new TGeoHMatrix;
+ IdealPosition(i,fM[i]);
+ } else {
+ TGeoPhysicalNode *pnode = pne->GetPhysicalNode();
+ if(pnode) fM[i]=pnode->GetMatrix();
+ else {
+ fM[i]=new TGeoHMatrix;
+ IdealPosition(i,fM[i]);
+ }
+ }
+ } else{
fM[i]=new TGeoHMatrix;
IdealPosition(i,fM[i]);
}
// Construct ideal position matrix for a given chamber
// Arguments: iCh- chamber ID; pMatrix- pointer to precreated unity matrix where to store the results
// Returns: none
- const Double_t kAngHor=19.5; // horizontal angle between chambers 19.5 grad
- const Double_t kAngVer=20; // vertical angle between chambers 20 grad
- const Double_t kAngCom=30; // common HMPID rotation with respect to x axis 30 grad
- const Double_t trans[3]={490,0,0}; //center of the chamber is on window-gap surface
- pMatrix->RotateY(90); //rotate around y since initial position is in XY plane -> now in YZ plane
- pMatrix->SetTranslation(trans); //now plane in YZ is shifted along x
+ const Double_t kAngHor=19.5; // horizontal angle between chambers 19.5 grad
+ const Double_t kAngVer=20; // vertical angle between chambers 20 grad
+ const Double_t kAngCom=30; // common HMPID rotation with respect to x axis 30 grad
+ const Double_t kTrans[3]={490,0,0}; // center of the chamber is on window-gap surface
+ pMatrix->RotateY(90); // rotate around y since initial position is in XY plane -> now in YZ plane
+ pMatrix->SetTranslation(kTrans); // now plane in YZ is shifted along x
switch(iCh){
case 0: pMatrix->RotateY(kAngHor); pMatrix->RotateZ(-kAngVer); break; //right and down
case 1: pMatrix->RotateZ(-kAngVer); break; //down